KR20190141455A - Hydrogen generating device - Google Patents

Abstract

According to an embodiment of the present invention, an oxyhydrogen generation device comprises: first and second positive electrode plates having first and second positive electrode accommodating units, respectively, formed with a path through which water flows on one surface thereof, and electrically connected to positive electrodes; a third positive electrode plate having a third positive electrode accommodating unit formed with paths through which water flows on both surfaces thereof, and electrically connected to positive electrodes; first and second negative electrode plates disposed between the first to third positive electrode plates, respectively, having first and second negative electrode accommodating units formed on both surfaces thereof, respectively, and electrically connected to negative electrodes; and first to fourth insulating plates disposed between the first to third positive electrode plates and the first and second negative electrode plates, respectively, and insulating the first to third positive electrode plates and the first and second negative electrode plates, wherein the first to third positive electrode plates have first to third inlets through which water is supplied to the first to third positive electrode accommodating units and first to third outlets through which water is discharged from the first to third positive electrode accommodating units, respectively, and the first to second negative electrode plates have first and second exhaust holes through which water including hydrogen gas is discharged from the first and second negative electrode accommodating units, respectively.

Description

Brown gas generator {HYDROGEN GENERATING DEVICE}

The present invention relates to a brown gas generator, and more particularly to a brown gas generator for generating hydrogen by electrolysis of water.

The brown gas generator using electrolysis is an apparatus in which oxygen gas is generated on the anode side and hydrogen gas is generated on the cathode side as the water molecules are decomposed by applying electrical energy to water containing an electrolyte or the like.

The Brown gas generator is developed and used in a variety of devices. In general, a pair of cases are provided with inlets and outlets through which water is introduced and discharged, a cathode plate and a cathode plate are disposed in the case, and an ion membrane is disposed between the anode plate and the cathode plate. In addition, as water passes through spaces formed at both sides of the case based on the ion membrane, the positive electrode plate, and the negative electrode plate, water molecules may be decomposed by electric energy to generate hydrogen and oxygen.

The conventional Brown gas generator as described above uses a case made of an insulator such as a synthetic resin, and arranges the ion membrane, the positive electrode plate, and the negative electrode plate in close contact with the case formed of the insulator.

In this case, various studies have been made to extend the contact time of water with the ion membrane, the positive electrode plate and the negative electrode plate in the Brown gas generator. Conventionally, a method of forming a water channel so that water can travel along a specific path inside the case and complicating the path of water introduced into the case has been used to slow the flow of water.

The conventional Brown gas generator as described above has an efficiency of generating hydrogen by decomposing water because it controls only the time that water is in contact with the positive electrode plate and the negative electrode plate even when the water flow path is delayed to form a flow path in the case. There is a problem with limitations.

Republic of Korea Patent Publication No. 10-2018-0045597 (2018.05.04) Republic of Korea Patent No. 10-1773022 (2017.08.24.) Republic of Korea Patent Publication No. 10-2017-0036228 (2017.04.03) Republic of Korea Patent No. 10-1630165 (2016.06.08) Republic of Korea Patent Publication No. 10-2015-0101696 (2015.09.04) Republic of Korea Patent No. 10-0704955 (2007.04.02) Japanese Patent Laid-Open No. 2009-114498 (2009.05.28) Japanese Patent No. 4142039 (2008.06.20) Japanese Utility Model Registration No. 3126047 (2006.09.20) Japanese Patent No. 3570429 (2004.07.02) Japanese Patent No. 3567138 (2004.06.18) Japanese Patent No. 2003-328169 (2003.11.19)

The problem to be solved by the present invention is to provide a Brown gas generator that can maximize the efficiency of generating hydrogen.

Brown gas generating apparatus according to an embodiment of the present invention, the first and second anode receiving portion is formed with a path through which water flows on the inside, respectively, the first and second anode plate electrically connected to the positive electrode; A third positive electrode plate having a third positive electrode accommodating part having water paths formed therein on both surfaces thereof, and having a positive electrode electrically connected thereto; First and second negative electrode plates disposed between the first to third positive electrode plates, respectively, and having first and second negative electrode accommodating portions formed on both surfaces thereof, and the negative electrodes being electrically connected to each other; Disposed between the first to third positive electrode plates and the first and second negative electrode plates, respectively, and including first to fourth insulating plates to insulate the first to third positive electrode plates and the first and second negative electrode plates. The first to third anode plates may include first to third inlets through which water is supplied to the first to third anode receivers, and first through third outlets through which water is discharged from the first to third anode receivers. Three outlets may be formed, respectively, and first and second exhaust ports may be formed in the first and second negative electrode plates through which water containing hydrogen gas is discharged from the first and second negative electrode accommodation portions, respectively.

In addition, first to third anode path portions are formed on the first to third anode receiving portions respectively formed on the first to third anode plates, and the first anode path portion is one direction from the first to second inlets. Are respectively extended to the second anode path portion, the second anode path portion is formed to extend from the first to the third outlet to the other term, respectively, the third anode path portion, the first and second anode path portion One or more may be formed between the first and second anode path portions to be connected.

In addition, first and third negative electrode path portions are formed in the first and second negative electrode accommodating portions respectively formed on the first and second negative electrode plates, and the first negative electrode path portions extend in one direction and are formed. The second cathode path portion is formed to be spaced apart from the side parallel to the first cathode path portion, the third cathode path portion is formed between the first and second cathode path portion to form one or more; Can be.

In this case, each of the first to third positive electrode plates further includes first to third positive electrode connection parts to which positive electrodes of DC power supplied from the outside are respectively connected, and the first and second negative electrode plates are connected to the upper end from the outside. First and second negative electrode connector may be formed to connect the negative electrode of the supplied DC power supply, respectively.

In addition, at least one path hole connecting the first and second negative electrode accommodating parts formed on both surfaces of the first and second negative electrode plates may be formed.

According to the present invention, an area in contact with water and a positive electrode plate is formed by forming a path through which water can flow in the positive electrode plate and the negative electrode plate, without using a separate positive electrode plate and negative electrode plate in the case of an insulating insulator. Since it can be maximized, there is an effect that can maximize the amount of hydrogen that can occur at the same time.

As the first to third anode path portions are formed in a zigzag form, a complicated path is formed from the inlet port in which water is introduced to the anode receiver formed in the anode plate to the outlet port through which water is discharged. have.

1 is a perspective view showing a brown gas generator according to an embodiment of the present invention.
2 is an exploded perspective view showing a brown gas generator according to an embodiment of the present invention.
3 is a perspective view illustrating a first anode plate of a brown gas generator according to an embodiment of the present invention.
4 is a perspective view illustrating a third anode plate of the brown gas generator according to the embodiment of the present invention.
5 is a perspective view illustrating a cathode plate of the Brown gas generator according to the embodiment of the present invention.
FIG. 6 is a cross-sectional view taken along the line AA ′ of FIG. 5.
7 is a schematic diagram illustrating a brown gas collecting device using the brown gas generating device according to an embodiment of the present invention.

Preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a perspective view showing a brown gas generator according to an embodiment of the present invention. 2 is an exploded perspective view showing a brown gas generator according to an embodiment of the present invention. 3 is a perspective view illustrating a first anode plate of a brown gas generator according to an embodiment of the present invention, and FIG. 4 is a third anode plate of a brown gas generator according to an embodiment of the present invention. Perspective view. 5 is a perspective view illustrating a cathode plate of a brown gas generator according to an embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along the line AA ′ of FIG. 5.

1 and 2, the brown gas generator 100 according to an embodiment of the present invention includes a first anode plate 110, a second anode plate 120, a third anode plate 130, The first cathode plate 140, the second cathode plate 150, the first insulation plate S1, the second insulation plate S2, the third insulation plate S3, and the fourth insulation plate S4 are included. .

As illustrated in FIGS. 1 and 2, the first anode plate 110 may be formed in a rectangular or square shape. And the positive electrode connecting portion 118 for connecting the electrode in the upper direction may be formed to protrude.

The first anode plate 110 may include a first anode body 111, a first inlet 112, a first outlet 114, a first anode receiver 116, and a first positive electrode connector 118. It includes.

As shown in the drawing, the first anode body 111 is formed in a rectangular or square shape. The first anode body 111 may be made of metal, and in this embodiment, may be manufactured using titanium, and may be manufactured by plating platinum on titanium. Accordingly, the first anode body 111 may increase corrosion resistance and chemical resistance, and may prevent contamination of water, which is an electrolyte, even when water is ionized. At this time, the metal used for the first positive electrode body 111 and the material to be plated may use other types of materials as necessary.

In addition, a plurality of coupling holes C1 may be formed in the first anode body 111. As shown in FIGS. 2 and 3, the plurality of coupling holes C1 may be formed along the edge of the first anode body 111, and in this embodiment, surround the first anode receiving portion 116. Twelve can be formed.

The first inlet part 112 may be provided to supply water to the inside of the first anode body 111 and may be disposed outside the first anode body 111. In the present embodiment, as will be described later, when the position where the first positive electrode connecting portion 118 is formed on the first positive electrode body 111 is defined as an upper portion, the first inlet portion 112 is an outer upper portion of the first positive electrode body 111. Can be placed in a biased position. Accordingly, as shown in FIG. 2, the first inlet 112a may be formed inside the first inlet 112.

The first discharge part 114 may be provided to discharge water supplied into the first positive electrode body 111 and may be disposed outside the first positive electrode body 111. In addition, the first inlet 112 may be disposed at a position biased to the outer lower portion of the anode matrix. Accordingly, as shown in FIG. 2, the first outlet 114a may be formed inside the first outlet 114.

In this embodiment, the position where the first inlet 112 and the first outlet 114 are disposed is diagonally directed to the edge side in the first anode body 111 having a rectangular or square shape as shown in FIG. 2. Can be placed in. Here, the water discharged through the first discharge unit 114 may include oxygen generated by electrolysis.

The first anode receiving portion 116 may be formed inside the first anode body 111, and as shown in FIGS. 2 and 3, may be formed in a predetermined groove shape on the inner surface. In the present exemplary embodiment, the first positive electrode accommodating part 116 is a space in which water introduced through the first inlet 112a may be filled, and the first first − accommodating part 116 may be filled with water. A first anode path portion 116a, a 1-2 anode path portion 116b, and a 1-3 anode path portion 161c may be formed.

The first-first anode path portion 116a may be formed in a straight line shape having a predetermined length in the downward direction at the first inlet 112a, and may be formed to have a predetermined width and a predetermined depth. The first and second anode path portions 116b may be formed in a straight line shape having a predetermined length in an upward direction at the first discharge port 114a and may be formed to have a predetermined width and a predetermined depth. . In this case, the lengths, widths, and depths of the first-first anode path portion 116a and the first-second anode path portion 116b may be the same, and may be disposed side by side at positions spaced apart from each other.

A plurality of first-third anode path portions 116c may be formed to connect the first-first anode path portion 116a and the first-second anode path portion 116b to each other. In the present embodiment, the 1-3 anode path portion 116c is formed in a direction perpendicular to the 1-1st anode path portion 116a and the 1-2 anode path portion 116b, and FIGS. 2 and 3. As shown in, it may be formed in a horizontal direction. In addition, the 1-3 anode path portion 116c may be formed to have a predetermined width and a predetermined depth, and the width and depth of the 1-3 anode path portion 116c may correspond to the first-first anode path portion ( The width and the depth of the 116a and the first and second anode path portions 116b may be smaller than the width and depth of the first and second anode path portions 116b.

The first positive electrode connecting portion 118 is disposed on an upper side of the first positive electrode body 111. The first positive electrode connector 118 is provided to connect an external power source to the first positive electrode plate 110, and a first positive electrode connector E1 may be formed to connect the external power source. In this embodiment, the first positive electrode connecting portion 118 is provided to connect the positive power of the external power.

The second anode plate 120 includes a second anode body 121, a second inlet 122, a second outlet 124, a second anode receiving portion and a second anode connecting portion 128. In this case, the second positive electrode plate 120 has the same structure as the first positive electrode plate 110 and is rotated by 180 degrees with respect to the vertical axis passing through the center of the first positive electrode plate 110. That is, although not shown in the drawing, the second positive electrode accommodating part is formed inside the second positive electrode plate 120, and the second positive accommodating part is formed in the same shape as the first positive accommodating part 116. In this case, as illustrated in FIGS. 1 and 2, the second positive electrode connecting portion 128 may be disposed at an upper side of the upper portion at the same position as the first positive electrode connecting portion 118.

In addition, a second positive electrode connector E2 may be formed in the second positive electrode connector 128. As shown in the drawing, a second positive electrode connector 128 may be formed at a position corresponding to the plurality of coupling holes C1 formed in the first positive electrode body 111. A plurality of coupling holes C2 may be formed in the anode body 121.

The third positive electrode plate 130 may include a third positive electrode body 131, a third inlet 132, a third discharge part 134, a third positive electrode receiving part 136, and a third positive electrode connecting part 138. Include. As illustrated in FIG. 2, the third positive electrode plate 130 may have a shape similar to that of the first positive electrode plate 110.

The third anode body 131 may be formed of the same metal as the first and second anode bodies 111 and 121, and the plurality of coupling holes C3 are disposed to surround the third anode receiving portion 136. Can be.

The third inlet 132 may be provided to supply water into the third anode body 131, and may be disposed on an upper side of the third anode body 131. When the third anode connection part 138 is formed on the third positive electrode body 131 at the position where the upper portion is defined, the third inlet 132 may be disposed at a position biased on the upper side of the third positive electrode body 131. .

The third discharge part 134 is provided to discharge the water supplied into the third positive electrode body 131 and may be disposed on the side of the third positive electrode body 131. In this case, the third discharge part 134 may be disposed on a side opposite to the third inlet part 132 and may be disposed under the side surface.

The third anode receiving portion 136 may be formed on the other surface which is one surface and the back surface of the third anode body 131, respectively. Further, a detailed description of the shape of the third positive electrode accommodating part 136 will be described later, but the third inlet 132a formed inside the third inlet 132 is extended to the third positive accommodating part 136. The third discharge port 134a formed in the third discharge part 134 may be extended to be formed.

As shown in FIG. 4, the third positive electrode accommodating part 136 has a 3-1 positive electrode path part 136a, a third-2 positive path part 136b and a third-3 positive electrode path part 136c. Can be formed.

The 3-1 anode path portion 136a may be formed to have a predetermined width and a predetermined depth in the shape of a straight line having a predetermined length in the downward direction at the third inlet 132a. In addition, the 3-2 anode path portion 136b may be formed in a straight shape having a predetermined length in the upper direction at the third discharge port 134a and may be formed to have a predetermined width and a predetermined depth. . In this case, the lengths, widths, and depths of the 3-1 anode path portion 136a and the second anode path portion 136b may be the same, and may be disposed side by side at positions spaced apart from each other.

A plurality of the 3rd-3rd anode path portions 136c may be formed to connect the 3-1 anode path portion 136a and the 3-2 anode path portion 136b with each other. In the present embodiment, the 3rd-3rd anode path part 136c is formed in the direction perpendicular to the 3-1st anode path part 136a and the 3-2nd anode path part 136b, and FIG. 2 and FIG. As shown in, it may be formed in a horizontal direction. The 3-3 anode path portion 136c may be formed to have a predetermined width and a predetermined depth, and the width and depth of the 3-3 anode path portion 136c may correspond to the 3-1 anode path portion ( 136a) and the width and depth of the 3-2 anode path portion 136b, respectively.

The third positive electrode connecting portion 138 is disposed at an upper side of the third positive electrode body 131. The third positive electrode connector 138 is provided to connect an external power source to the third positive electrode plate 130, and a third positive electrode connector E3 may be formed to connect the external power source. In this embodiment, the third positive electrode connecting portion 138 is provided to connect the positive power of the external power.

The first cathode plate 140 may be formed in a rectangular or square shape as shown in FIGS. 1, 2, and 5. The first negative electrode plate 140 includes a first negative electrode body 141, a fourth discharge part 142, and a first negative electrode receiving part 146.

In addition, a first negative electrode connector E4 may be formed to connect the electrode in an upward direction. The first negative electrode connector E4 is formed in the shape of a groove on the top surface of the first negative electrode body 141. Accordingly, the negative electrode of the external power source can be connected through the negative electrode connector E3.

As illustrated, the first cathode body 141 is formed in a rectangular or square shape. And the first cathode body 141, like the first anode body 111, a metal may be used, in this embodiment, may be manufactured using titanium, may be manufactured by plating platinum on titanium. have. Accordingly, the first negative electrode body 141 may increase corrosion resistance and chemical resistance, and may prevent contamination of water, which is an electrolyte even if water is ionized. If necessary, the metal used for the first cathode body 141 and the material to be plated may be used with other kinds of materials as necessary.

In addition, a plurality of coupling holes C4 may be formed in the first cathode body 141. As illustrated in FIGS. 1 and 2, the plurality of couplers C4 may be formed along the edge of the first cathode body 141, and the plurality of couplers C1 formed on the first anode body 111. It may be disposed at a position corresponding to). In the present exemplary embodiment, twelve coupling holes C4 may be formed to surround the first cathode receiving part 146.

The fourth discharge part 142 is provided to exhaust hydrogen gas, which is a gas generated in the first negative electrode accommodating part 146 formed inside the first negative electrode body 141, to the outside, and the first negative electrode body 141 is provided. It may be disposed at the upper end of the. In the present embodiment, the fourth discharge part 132 may be disposed at a position biased to the upper end of the first negative electrode body 141. Accordingly, as shown in FIG. 5, a fifth outlet 142a may be formed in the fourth outlet 142.

In the present embodiment, the fourth discharge part 142 may be disposed at the upper end of the first negative electrode body 141 having a rectangular or square shape, as shown in FIGS. 1, 2, and 5. The fourth discharge part 142 is disposed at the upper end, as shown in FIG. 5, since the hydrogen gas is moved upward through the first negative electrode accommodating part 146 formed in the first negative electrode body 141. It is good to be placed in.

The first negative electrode accommodating part 146 may be formed inside the first negative electrode body 141, and may be formed in a predetermined groove shape on the inner side as illustrated in FIG. 5. In the present embodiment, the first negative electrode accommodating part 146 may be formed at a position corresponding to the first positive electrode accommodating part 116, and the first negative electrode path part 146a, the second negative electrode path part 146b, and The third cathode path part 146c may be formed. Here, the first negative electrode accommodating part 146 may be formed on both sides of the first negative electrode body 141, and the first negative electrode accommodating part 146 formed on both sides of the first negative electrode body 141 may have the same shape. Can be formed.

In the present exemplary embodiment, the first cathode path part 146a may be formed in a straight line shape having a predetermined length in the horizontal direction, and may have a predetermined width and a predetermined depth. Can be formed. In this case, the fourth discharge part 142 may be disposed in the center of the first cathode path part 146a.

The second cathode path part 146b may be formed in parallel with the first cathode path part 146a at a position spaced apart from each other, and may have a predetermined width and a predetermined depth. In this case, the first cathode path part 146a and the second cathode path part 146b may have the same length, width, and depth.

The third cathode path part 146c may be formed in plural to connect the first cathode path part 146a and the second cathode path part 146b with each other. In this embodiment, the third cathode path portion 146c is formed to connect the first cathode path portion 146a and the second cathode path portion 146b, and is formed in the vertical direction, as shown in FIG. 5. Can be. The third cathode path part 146c may be formed to have a predetermined width and a predetermined depth, and the width and depth of the third cathode path part 146c may be the first cathode path part 146a and the second cathode. It may be smaller than the width and depth of the path portion 146b, respectively.

The second negative electrode plate 150 includes a second negative electrode body 151, a fifth discharge part 152, and a second negative electrode receiving part 156. In this case, as shown in FIG. 2, the second negative electrode plate 150 has the same structure as the first negative plate 140. That is, the second negative electrode receiving portion 156 is formed on both surfaces of the second negative electrode body 151 of the second negative electrode plate 150.

In addition, a second negative electrode connector E5 may be formed on an upper surface of the second negative electrode body 151, and as shown, a position corresponding to a plurality of coupling holes C4 formed in the first negative electrode body 141. In the second cathode body 151, a plurality of coupling holes C5 may be formed.

The first to fourth insulating plates S1, S2, S3, and S4 have a rectangular shape similar to the shapes of the first to third positive electrode bodies 111, 121, and 131 and the first and second negative electrode bodies 141 and 151. Or it may have a square shape, and the first to fourth holes (SH1, SH2, SH3, SH4) may be formed inside.

The first insulating plate S1 is disposed between the first positive electrode body 111 and the first negative electrode body 141, and an insulating material so that the first positive electrode body 111 and the first negative electrode body 141 are insulated from each other. It can be prepared as. The second insulating plate S2 is disposed between the first negative electrode body 141 and the third positive electrode body 131, and an insulating material so that the first negative electrode body 141 and the third positive electrode body 131 are insulated from each other. It can be prepared as. The third insulating plate S3 is disposed between the third positive electrode body 131 and the second negative electrode body 151, and an insulating material to insulate the third positive electrode body 131 and the second negative electrode body 151 from each other. It can be prepared as. The fourth insulating plate S4 is disposed between the second negative electrode body 151 and the second positive electrode body 121 and insulates the second negative electrode body 151 and the second positive electrode body 121 from each other. It can be prepared as.

 In the present exemplary embodiment, the first to fourth insulating plates S1, S2, S3, and S4 may be made of silicon, synthetic resin, or the like. Any material may be used as long as the material can insulate between the second cathode bodies 141 and 151.

In addition, the first to fourth insulating plates S1, S2, S3, and S4 may be formed relatively thinly as illustrated, and may include the first to third anode bodies 111, 121, 131, and the first and the first 2 may vary depending on the power applied to the cathode bodies 141 and 151, but is not limited thereto.

The first to fourth insulating plates S1, S2, S3, and S4 are disposed between the first to third anode bodies 111, 121, and 131 and the first and second cathode bodies 141 and 151, respectively. The first to third anode bodies 111, 121, and 131 and the first and second cathode bodies 141 and 151 are coupled to each other by a bolt B or the like. Water introduced into the first to third positive electrode accommodating parts 116, 126, and 136 through the 121 and 131 and the first and second negative electrode bodies 141 and 151, or the first and second negative electrode accommodating parts ( It is possible to prevent the hydrogen gas generated at 146 and 156 from being discharged to the outside. Accordingly, as shown in FIG. 2, a plurality of couplers may be formed in the first to fourth insulating plates S1, S2, S3, and S4, and the plurality of couplers may include the first to third anode bodies 111. , 121, 131, and coupling holes C1, C2, C3, C4, and C5 formed in the first and second cathode bodies 141 and 151, respectively.

At this time, the first to third anode body 111, 121, 131 and the first and second cathode body (141, 151) by the bolt (B) to prevent each of the coupling holes (C1, C2) , C3, C4 and C5 may be disposed to penetrate the insulating tube S. The insulating tube S is configured to electrically insulate the first to third anode bodies 111, 121, 131 and the first and second cathode bodies 141, 151, and may be made of silicon, rubber, or synthetic resin. Can be prepared.

In addition, first to fourth holes SH1, SH2, SH3, and SH4 are formed in each of the first to fourth insulating plates S1, S2, S3, and S4, and the first to fourth holes SH1, SH2, The sizes of the SH3 and the SH4 may be formed to correspond to the sizes of the first to third positive electrode accommodating parts 116, 126, and 136 and the first and second negative electrode accommodating parts 146 and 156. In the present embodiment, the overall shape of the first to third positive electrode accommodating parts 116, 126, and 136 and the first and second negative electrode accommodating parts 146 and 156 may be formed in a rectangular or square shape. The shape of the four holes SH1, SH2, SH3, and SH4 may also be formed in a rectangular or square shape.

Referring to the operation of the Brown gas generator 100 according to the present embodiment, each of the first to third positive electrode connector (E1, E2, E3) of the first to third anode plate (110, 120, 130) The positive pole of the DC power is connected, and the negative pole of the DC power is connected to each of the first and second negative electrode connectors E4 and E5 of the first and second negative electrode plates 140 and 150. When water is supplied through the first to third inlets 112, 122, and 132 formed on the first to third anode plates 110, 120, and 130, the first to third inlets 112a, 122a, and 132a. Water is filled in the first to third positive electrode accommodating parts 116 and 136 through the contact with the water and the first to third positive electrode plates 110, 120 and 130, and the water is electrolyzed. Is generated.

The electrolyzed hydrogen gas is collected at the first and second negative electrode accommodating parts 146 and 156 which are the negative electrodes, and the oxygen gas is disposed at the first to third positive electrode accommodating parts 116 and 136 which are the positive electrodes. Gather. At this time, the water introduced into the first to third anode receiving portions 116 and 136 through the first to third inlet 112a, 122a, and 132a is formed on the entire first to third anode receiving portions 116 and 136. It spreads over and may be discharged to the outside through the first to third outlets 114a, 124a, and 134a together with the generated oxygen gas. In addition, the hydrogen gas collected on the first and second cathode receiving portions 146 and 156 formed on both surfaces of the first and second cathode bodies 141 and 151 may have first and second exhaust ports 142a and 152a formed thereon. Can be discharged through).

In this embodiment, direct current power is applied to the first to third positive electrode plates 110, 120, 130 and the first and second negative electrode plates 140, 150. The direct current power source having a voltage of 12 V and a current of 20 A is applied. Supply. Accordingly, as the current of 20A is supplied, about 320 ml of hydrogen gas may be discharged through the fourth and fifth discharge parts 142 and 152.

In addition, since water is rapidly introduced through the first to third positive electrode plates 110, 120, and 130, the first to third electrodes are compared with a case in which a water receiving space is formed in a case provided separately from the positive electrode plate or the negative electrode plate. Water may quickly flow into the first to third anode receiving portions 116 and 136 formed on the three anode plates 110, 120, and 130, respectively.

5 and 6, the first and second negative electrode accommodating parts 146 and 156 formed on the first and second negative electrode plates 140 and 150 will be described in more detail. As described above, the first and second negative electrode accommodating parts 146 and 156 may be formed on both surfaces of the first and second negative electrode bodies 141 and 151, respectively.

As described above, the first and second cathode accommodating parts 146 and 156 include a first cathode path part 146a, a second cathode path part 146b, and a third cathode path part 146c, respectively. The first cathode path part 146a, the second cathode path part 146b, and the third cathode path part 146c are formed in the shape of the grooves formed on the inner surfaces of the first and second cathode body 141 and 151, respectively. Can be.

The first cathode path part 146a and the second cathode path part 146b are formed at positions spaced apart from each other in parallel to each other, as shown in the vertical direction. In addition, a plurality of third cathode path parts 146c may be provided between the first cathode path part 146a and the second cathode path part 146b in a horizontal direction. The third cathode path portions 146c are formed to be spaced apart from each other at regular intervals, and the plurality of third cathode path portions 146c are the same as the inner surfaces of the first and second cathode bodies 141 and 151. Placed on a plane.

In addition, as illustrated in FIG. 5, a plurality of third cathode path portions 146c may be provided with holes for connecting between adjacent third cathode path portions 146c. These holes may be formed in the vertical direction to connect the adjacent third cathode path portions 146c formed in the horizontal direction to each other. Such a plurality of holes may be arranged regularly according to a predetermined rule as shown, but is not limited thereto, and may be arranged irregularly.

In this case, the widths of the first cathode path part 146a and the second cathode path part 146b may be greater than the width of the third cathode path part 146c, and in this embodiment, the third cathode path part 146c The width of may be about 60% (error range 10%) of the width of the first cathode path portion 146a and the second cathode path portion 146b. In addition, the depths of the first cathode path part 146a and the second cathode path part 146b may be deeper than the depth of the third cathode path part 146c.

As the first cathode path part 146a, the second cathode path part 146b, and the third cathode path part 146c are formed in the negative electrode accommodating part 146 as described above, the hydrogen formed by electrolysis is formed in the first part. Movement along the cathode path part 146a, the second cathode path part 146b, and the third cathode path part 146c may be discharged to the outside through the fifth outlet 142a.

Here, as illustrated in FIG. 5, the fifth outlet 142a may be disposed in the center of the third cathode path portion 146c disposed at the top thereof and may be formed through the first cathode body 141. have. And it may be formed to be connected to the fourth outlet 142 is connected to the top from the center of the fifth outlet 142a penetrating the first cathode body 141.

Accordingly, the hydrogen gas collected in the first negative electrode accommodating part 146 formed on both surfaces of the first negative electrode body 141 may be discharged to the outside through the fifth outlet 142a.

5 and 6, a plurality of path holes 146d may be formed in the first cathode path part 146a and the second cathode path part 146b. The plurality of path holes 146d are provided to connect the first cathode receiving portions 146 formed on both sides of the first cathode body 141, and the hydrogen gas collected in each of the first cathode receiving portions 146 may move with each other. It is formed to be.

7 is a schematic diagram illustrating a brown gas collecting device using the brown gas generating device according to an embodiment of the present invention.

Referring to FIG. 7, a brown gas collecting device 200 for capturing hydrogen generated by the brown gas generating device 100 according to the present embodiment will be described.

As illustrated, the brown gas collecting device 200 includes a brown gas generating device 100, a water storage unit 210, and a gas purifying unit 220. The water reservoir 210 is connected to the first to third inlets 112, 122, and 132 of the brown gas generator 100 through the water supply pipe 212. The first to third discharge parts 114, 124, and 134 of the brown gas generator 100 are connected to the first water discharge pipe 214, and the water discharged through the first water discharge pipe 214 may be separated. It may be stored in the storage unit, it may be recovered to the water storage unit 210 as needed. Here, the water discharged through the first water discharge pipe 214 is water containing oxygen gas.

The fourth and fifth discharge parts 142 and 152 of the brown gas generator 100 are connected to the second water discharge pipe 216. The water discharged through the second water discharge pipe 216 is water containing hydrogen gas.

The water discharged into the first water discharge pipe 214 and the second water discharge pipe 216 is connected to the integrated discharge pipe 222 and merged into one. The integrated discharge pipe 222 is connected to the gas purification unit 220. Accordingly, the water including the hydrogen gas and the water including the oxygen gas are supplied to the gas purification unit 220 in the integrated discharge pipe 222. The gas purification unit 220 may be partially filled with water, and water containing hydrogen gas and oxygen gas supplied through the integrated discharge pipe 222 may be supplied into the water filled in the gas purification unit 220 to be filled with water. Brown gas mixed with purified hydrogen gas and oxygen gas may be discharged through the refinery gas exhaust pipe 224. Brown gas discharged to the refinery gas exhaust pipe 224 may be supplied to an external device. At this time, the generated brown gas may be used for industrial purposes.

The positive electrode terminal 232 may be electrically connected to the first to third positive electrode connectors 118, 128, and 138, and the negative electrode terminal 234 may be electrically connected to the first and second negative electrode connectors E4 and E5. . In this case, the power supplied to the Brown gas generator 100 through the positive electrode terminal 232 and the negative electrode terminal 234 is DC power.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings. However, since the above-described embodiments have only been described by way of example, the present invention is limited to the above embodiments. It should not be understood, the scope of the present invention will be understood by the claims and equivalent concepts described below.

100: Brown gas generator
110: first anode plate 111: first anode body
112: first inlet 112a: first inlet
114: first outlet 114a: first outlet
116: first anode receiving portion 116a: first-first anode path portion
116b: 1-2th anode path portion 116c: 1-3rd anode path portion
118: first positive electrode connection portion
120: second anode plate 121: second anode body
122: second inlet 124: second outlet
128: second positive electrode connection portion
130: third anode plate 131: third anode body
132: third inlet 132a: third inlet
134: third outlet 134a: third outlet
136: third anode receiving portion 136a: 3-1 anode path portion
136b: 3-2 anode path portion 136c: 3-3 anode path portion
138: third positive electrode connection portion
140: first cathode plate 141: first cathode body
142: fourth outlet 142a: fifth outlet
146: first negative electrode accommodating portion 146a: first negative electrode path portion
146b: second cathode pathway portion 146c: third cathode pathway portion
146d: path hole
150: second cathode plate 151: second cathode body
152: fifth discharge part 156: second negative electrode accommodation part
S1, S2, S3, S4: first to fourth insulating plates
SH1, SH2, SH3, SH4: first to fourth holes
E1, E2, E3: first to third positive electrode connector
E4, E5: first and second negative electrode connector
C1 ~ C5: Coupling Sphere
B: Bolt S: Insulated Tube

Claims (5)

First and second positive electrode plates each having first and second positive electrode accommodating parts each having a flow path therein formed on one surface thereof and having positive electrodes electrically connected thereto;
A third positive electrode plate having a third positive electrode accommodating part having water paths formed therein on both surfaces thereof, and having a positive electrode electrically connected thereto;
First and second negative electrode plates disposed between the first to third positive electrode plates, respectively, and having first and second negative electrode accommodating portions formed on both surfaces thereof, and the negative electrodes being electrically connected to each other;
Disposed between the first to third positive electrode plates and the first and second negative electrode plates, respectively, and including first to fourth insulating plates to insulate the first to third positive electrode plates and the first and second negative electrode plates. and,
First to third inlets through which water is supplied to the first to third anode receivers and first to third outlets through which water is discharged from the first to third anode receivers, respectively. Are each formed,
And a first and a second exhaust port through which the water containing hydrogen gas is discharged from the first and second cathode receiving portions, respectively. The method according to claim 1,
First to third anode path portions are formed on the first to third anode receiving portions respectively formed on the first to third anode plates,
The first anode path portion extends in one direction from the first to second inlets, respectively,
The second anode path portion is formed to extend in the other direction from the first to third outlet, respectively,
And at least one third anode path portion formed between the first and second anode path portions so that the first and second anode path portions are connected to each other. The method according to claim 1,
First and third cathode path portions are formed in the first and second cathode receiving portions respectively formed on the first and second cathode plates,
The first cathode path portion is formed extending in one direction,
The second cathode path portion is formed spaced apart in parallel with the first cathode path portion,
And at least one third cathode path portion formed between the first and second cathode path portions to form the first and second cathode path portions. The method according to claim 1,
Each of the first to third positive electrode plates further includes first to third positive electrode connection parts connected to positive electrodes of a direct current power supplied from the outside, respectively.
The first and second negative electrode plates have a brown gas generator having first and second negative electrode connectors respectively connected to negative electrodes of a DC power source supplied from the outside at upper ends thereof. The method according to claim 1,
The brown gas generator of claim 1, wherein at least one path hole connecting the first and second cathode receiving portions formed on both surfaces of the first and second cathode plates is formed.

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